Presentation is loading. Please wait.

Presentation is loading. Please wait.

ELT Stellar Populations Science Near IR photometry and spectroscopy of resolved stars in nearby galaxies provides a way to extract their entire star formation.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "ELT Stellar Populations Science Near IR photometry and spectroscopy of resolved stars in nearby galaxies provides a way to extract their entire star formation."— Presentation transcript:

1 ELT Stellar Populations Science Near IR photometry and spectroscopy of resolved stars in nearby galaxies provides a way to extract their entire star formation and chemical enrichment histories Crowding is the limiting factor for photometry of bulges, disks, and the main bodies of elliptical galaxies; sensitivity will be limiting factor for regions with lower surface brightness (independent of aperture size) M31 observed with Gemini N+NIRI/Altair (Olsen et al. 2006) K HB ~23.5

2 Issues addressed through simulations Scientific Issues: Sample size needed Field size needed Filters needed Photometric Issues: Spatial variability of PSF Time variability of PSF Absolute calibration

3 PSF Simulation AO Error sources included 1.Finite number of guide stars and DMs 2.Finite spatial resolution of wavefront sensors and DMs Sampled on 7x7 20” wide grid in IJHK for 20-m, 30-m, 50-m, and 100-m telescopes Sampled over 12-minute average intervals from hour- long “typical” observation with TMT MASS/DIMM 5 atmospheric profiles  4 filters  49 positions  4 telescopes = 3920 PSFs

4 30-m J PSF grid, profile 1 Simulating a realistic observation Courtesy of Richard Clare

5 Simulation procedure Select appropriate population mix Pick stars from stellar isochrones and place in image, making sure to simulate stars well below crowding limit Convolve image with PSFs (49  5 convolutions, combine through weighted average) Add sky background and noise Perform PSF-fitting photometry Correct photometry for Strehl ratio using profile 1 or average of profiles 1 and 5 Derive best-fit population mix

6 “Raw” photometry With 1 PSF observationWith 2 PSF observations“Perfect” photometry 20-m to 100-m: M31 Bulge K HB ~23.5, K MSTO ~27

7 20-m to 100-m: M31 Bulge 20-m30-m 50-m100-m

8 An M31 Survey: 20-m Local Group Survey (Massey et al. 2002) image Name r()  K B/D K lim Time(s) F1 1.97 15.0 7.4 24.1 21.8 Bulge1 2.05 15.1 6.7 24.1 24.9 F177 2.79 15.4 5.5 24.4 38.3 F174 2.59 15.4 5.3 24.4 38.3 F3 3.80 15.8 3.8 24.7 66.9 Bulge2 3.83 16.0 3.1 24.9 87.8 F4 3.98 16.1 2.7 25.0 100 F5 5.84 16.4 2.0 25.2 147 F170 6.08 16.5 1.9 25.3 168 Disk2 9.09 17.1 1.1 25.7 348 F2 11.9 17.8 0.3 26.1 776 F280 20.5 18.4 0.2 26.6 1767 Disk1 56.9 19.6 0.0 27.8 17476 1 hour exposure, S/N=5: J: 28.9 H: 28.0 K: 27.0 K HB ~23.5, K MSTO ~27

Download ppt "ELT Stellar Populations Science Near IR photometry and spectroscopy of resolved stars in nearby galaxies provides a way to extract their entire star formation."

Similar presentations

Advanced CCD Workshop Arne A. Henden

Advanced CCD Workshop Arne A. Henden
A Crash Course in Radio Astronomy and Interferometry: 4

A Crash Course in Radio Astronomy and Interferometry: 4
Chronicling the Histories of Galaxies at Distances of 1 to 20 Mpc: Simulated Performance of 20-m, 30-m, 50-m, and 100-m Telescopes Knut Olsen, Brent Ellerbroek,

Chronicling the Histories of Galaxies at Distances of 1 to 20 Mpc: Simulated Performance of 20-m, 30-m, 50-m, and 100-m Telescopes Knut Olsen, Brent Ellerbroek,
General Astrophysics with TPF-C David Spergel Princeton.

General Astrophysics with TPF-C David Spergel Princeton.
To measure the brightness distribution of galaxies, we must determine the surface brightness of the resolved galaxy. Surface brightness = magnitude within.

To measure the brightness distribution of galaxies, we must determine the surface brightness of the resolved galaxy. Surface brightness = magnitude within.
Deep HST Imaging of M33: the Star Formation History

Deep HST Imaging of M33: the Star Formation History
The Galaxy Evolution Science Case for a Large Ground-based Telescope Betsy Gillespie December 4, 2002 Grateful acknowledgements to: Arjun Dey’s “Galaxy.

The Galaxy Evolution Science Case for a Large Ground-based Telescope Betsy Gillespie December 4, 2002 Grateful acknowledgements to: Arjun Dey’s “Galaxy.
Science Group: Status, Plans, and Issues Claire Max Liz McGrath August 19, 2008.

Science Group: Status, Plans, and Issues Claire Max Liz McGrath August 19, 2008.
Extragalactic AO Science James Larkin AOWG Strategic Planning Meeting September 19, 2004.

Extragalactic AO Science James Larkin AOWG Strategic Planning Meeting September 19, 2004.
Optimal Photometry of Faint Galaxies Kenneth M. Lanzetta Stony Brook University.

Optimal Photometry of Faint Galaxies Kenneth M. Lanzetta Stony Brook University.
Kinematics/Dynamics  Chemistry/dust  Stellar populations  Searches for z ~ 6-7 « Hot » scientific researches at VLT in cosmology Mass Galaxy formation/gas.

Kinematics/Dynamics  Chemistry/dust  Stellar populations  Searches for z ~ 6-7 « Hot » scientific researches at VLT in cosmology Mass Galaxy formation/gas.
PILOT: Pathfinder for an International Large Optical Telescope -performance specifications JACARA Science Meeting PILOT Friday March 26 Anglo Australian.

PILOT: Pathfinder for an International Large Optical Telescope -performance specifications JACARA Science Meeting PILOT Friday March 26 Anglo Australian.
Science Team Management Claire Max Sept 14, 2006 NGAO Team Meeting.

Science Team Management Claire Max Sept 14, 2006 NGAO Team Meeting.
The Need for Contiguous Fields NGAO Team Meeting, Waimea January 22, 2007 Claire Max.

The Need for Contiguous Fields NGAO Team Meeting, Waimea January 22, 2007 Claire Max.
Widening the Scope of Adaptive Optics Matthew Britton.

Widening the Scope of Adaptive Optics Matthew Britton.
TOPS 2003 Remote Obs 1 Karen Meech Institute for Astronomy TOPS 2003 Image copyright, R. Wainscoat, IfA Image courtesy K. Meech.

TOPS 2003 Remote Obs 1 Karen Meech Institute for Astronomy TOPS 2003 Image copyright, R. Wainscoat, IfA Image courtesy K. Meech.
NGAO Photometric Accuracy Budget Strategy Richard Dekany.

NGAO Photometric Accuracy Budget Strategy Richard Dekany.
A Short Presentation of Ongoing AO Work at Lund Observatory Mette Owner-Petersen Lund Observatory Workshop for “Forskarskolen i Rymdteknik” Gothenburg.

A Short Presentation of Ongoing AO Work at Lund Observatory Mette Owner-Petersen Lund Observatory Workshop for “Forskarskolen i Rymdteknik” Gothenburg.
KDUST Supernova Cosmology

KDUST Supernova Cosmology
NGAO Status R. Dekany January 31, 2008. 2 Next Generation AO at Keck Nearing completion of 18 months System Design phase –Science requirements and initial.

NGAO Status R. Dekany January 31, Next Generation AO at Keck Nearing completion of 18 months System Design phase –Science requirements and initial.

Similar presentations

Ads by Google